Patent Application
20210254919
The present invention is directed to a rifled barrel for firing ammunition projectiles, which includes a bullet and casing wherein the bullet and casing are of a type used with firearms, either breechloader or muzzleloader firearms. The barrel includes a rifled portion and a non-rifled portion, wherein the rifled portion extends longitudinally from a muzzle of the barrel toward the non-rifled portion. The non-rifled portion of the barrel extends longitudinally from an opposite end of the barrel located adjacent to a loading chamber or breech of the firearm toward the rifled portion, and together the rifled and non-rifled portions form a continuous cylindrical channel through the rifled barrel.
There are two general classes of firearm: muzzleloader firearms and breechloader firearms. Most modern firearms are breechloader firearms, or a firearm in which a shell or cartridge is inserted or loaded into a chamber integral to a rear portion of a barrel. In contrast, most early firearms where muzzleloaders, or firearms wherein a projectile and propellant are loaded from a muzzle of the firearm. Breechloaders are the more popular and technologically advanced class of firearms. However, muzzleloaders are still used today by hunters, competitive shooters, and firearm enthusiasts. Both classes of firearms have their own associated operational issues relative to the barrel that are made more prominent over the course of use.
A main concern with muzzleloaders is barrel and breech fouling. Fouling is a built-up layer of particulates, including dirt, propellant residue, and moisture, along inner surfaces of the firearm's components. A main source of fouling is the propellant used in muzzleloaders. Black powder or a similar synthetic substitute is deposited into the barrel of the firearm via the muzzle, free from a shell or cartridge found in projectiles for breechloaders. Unfortunately, both black powder and synthetic substitutes for black powder are corrosive and hygroscopic. When either are ignited at discharge of the muzzleloader, the resulting residue attracts moisture. If left to settle the mixture of water moisture and propellant residue will form a layer on inner surfaces that will pit, rust, and corrode such surfaces.
Unfortunately, such layers often develop oftentimes after only one or two shots fired from the muzzleloader. To combat fouling, muzzleloader barrels are often seasoned to create a protective layer that is at least resistant to fouling. Such season often involves cleaning and heating the barrel before applying a lubricant. Cleaning the barrel removes contaminants and fouling. Heating the barrel causes the metal to expand and open pores in the barrel surface. Applying the lubricant into the heated barrel allows more lubricant to permeate farther into the barrel surface to create a protective barrier.
Loading a muzzleloader firearm after cleaning and before firing a further shot can be a strenuous task, as the components of the projectile fit tightly into the barrel. After seasoning a muzzleloader barrel and then firing it several times, it can be extremely difficult to load the muzzleloader with typical components. Sabots are typically used with muzzleloaders to properly align a bullet within a barrel and to create a proper gas seal around the bullet upon discharge and ignition of the propellant. However, sabots seat the bullet in a muzzle-facing seat and add to the diameter of the projectile in the barrel. Using sabots is necessary with some bullets, but exacerbates the difficulty with loading the projectile into the barrel of the muzzleloader. To ensure accuracy of the muzzleloader, the projectile must catch barrel rifling to properly spin and ensure a proper trajectory out of the barrel. For bullets of small caliber than the barrel from which they are fired, sabots are necessary to achieve this accuracy.
As such, there is a need in the muzzleloader art for a rifled barrel that is both easily loadable, even after several discharges from the firearm, and which also maintains a high level of accuracy during each shot.
With both breechloader and muzzleloader firearms, there is also an issue of land wear along two ends of the rifled barrel. In known rifled barrels, the transition between rifled and non-rifled portions of a barrel are not gradual. In other words, when looking along a cross-sectional length of a rifled barrel, the surface of the lands of the rifling is squared adjacent to the non-rifled portion. The force created by ignition of a propellant causes a violent collision between the bullet and squared land as the bullet initially contacts the lands of the rifled barrel. The collision and heat of repeated firing of the firearm wears the lands down predominantly at the ends of the rifled barrel, both at the breech and muzzle ends. Rifling land wear leads to reduced accuracy of projectiles fired from any rifled barrel, whether attached to a breechloader or a muzzleloader firearm. For automatic breechloader firearms that fire multiple projectiles in rapid succession, this issue is exacerbated.
It would be advantageous for a rifled barrel to include a transitional portion between a non-rifled portion and a rifled portion to further enhance accuracy of projectiles. Such a rifled barrel could also be advantageous with certain types of ammunition that are adapted to increase in diameter and circumference after being loaded into the rifled barrel. Such a rifled barrel would be advantageous for increasing accuracy in both breechloader and muzzleloader firearms.
It is a primary objective of this disclosure to teach a preferred embodiment of a rifled barrel having a cylindrical channel longitudinally extending within the rifled barrel between an oppositely oriented muzzle opening and a breach opening, the cylindrical channel having a rifled portion and a non-rifled portion, the rifled portion having a land and a groove helically extending along a surface of the cylindrical channel from the muzzle opening toward the breach opening, the non-rifled portion being smooth and having a consistent diameter along a length, wherein the diameter of the non-rifled portion of the cylindrical channel is equal to a diameter of the rifled portion measured between oppositely oriented sections of the groove, and wherein a diameter measured between oppositely oriented land sections of the rifled portion along a partial length adjacent to the non-rifled portion gradually increases until equaling the diameter of the non-rifled portion.
A further objective is to teach an embodiment of the rifled barrel wherein the length of the non-rifled portion is configured to accommodate a cylindrical body of a projectile.
Another objective is to teach an embodiment of the rifled barrel wherein the non-rifled portion of the cylindrical channel is insertably removable from the barrel through the breach opening.
A further objective is to teach an embodiment of a muzzleloader firearm having the preferred rifle barrel embodiment, or one of the alternative embodiments described herein.
Yet another objective of this disclosure is to teach a method of converting a fully rifled barrel to a partially rifled barrel, including grinding down lands located along an inner surface of the rifled barrel along a partial length of the barrel such that the lands are fully removed along the partial length to form a non-rifled portion, partially grinding down lands along the inner surface of the rifled barrel along a partial length of barrel adjacent to the non-rifled portion such that a diameter between oppositely oriented lands gradually decreases along the partial length toward a muzzle of the partially rifled barrel, and maintaining a consistent diameter throughout the length of the partially rifled barrel measured between oppositely oriented sides of the non-rifled portion and between oppositely oriented grooves of a rifled section of the partially rifled barrel.
A better understanding of the invention will be had with respect to the accompanying drawings wherein:
It will be appreciated that numerous specific details have been provided for a thorough understanding of the exemplary embodiments described herein. However, it will be understood by those of ordinary skill in the art that the embodiments described herein may be practiced without these specific details. In other instances, well-known methods, procedures and components have not been described in detail so as not to obscure the embodiments described herein. Furthermore, this description is not to be considered so that it may limit the scope of the embodiments described herein in any way, but rather as merely describing the implementation of the various embodiments described herein.
The description that follows, and the embodiments described therein, are provided by way of illustration of an example, or examples, of particular embodiments of the principles of the present invention. These examples are provided for the purposes of explanation, and not limitation, of those principles and of the invention. It will also be appreciated that similar structures between embodiments are marked with identical reference numbers for ease of reference.
The rifled barrel embodiments described herein are generally discussed relative to use with a muzzleloader firearm. However, the same rifled barrel embodiments may be used with breechloader firearms (i.e. non-muzzleloader firearms). Further, the firearms, either muzzleloaders or non-muzzleloaders, are not limited to rifles and handguns. The rifled barrel embodiments described herein may be used with any applicable firearm, including, but not limited to, handguns, long guns, rifles, shotguns, carbines, machine guns, submachine guns, automatic rifles, assault rifles, personal defense weapons, battle rifles, etc. The rifled barrel may also be used with any applicable ammunition, including sabots, bullets, rounds, etc.
A cylindrical channel 101 extends longitudinally through, preferably, a center of the rifled barrel 100. The cylindrical channel 101 is preferably coaxial with the rifled barrel 100, but may arranged in such a manner that it is not coaxial. The cylindrical channel 101 includes a rifled portion 106 and the non-rifled portion 108. The rifled portion 106 of the cylindrical channel 101 includes rifling in the form of lands 110 and grooves 112 extending helically, or in a spiraled pattern, along a surface of the cylindrical channel. The rifling, or lands 110 and grooves 112 together, of the rifled portion 106 extends from the muzzle end 102 towards the breech end 104 and ends adjacent to the non-rifled portion 108. The non-rifled portion 108 extends from the breech end 104 towards the muzzle end 102 along a partial length of the cylindrical channel 101 and meets with the rifled portion 106 along the length of the cylindrical channel between the breech end 104 and muzzle end 102. The non-rifled portion 108 does not have any lands 110, and therefore does not have corresponding grooves 112. The length of either the rifled portion 106 or the non-rifled portion 108 may vary between embodiments of the rifled barrel 100. Generally, however, the length of the rifled portion 106 will be greater than the length of the non-rifled portion 108 for reasons discussed further herein.
Lengths L′, L″, and L″′ are provided to provide directional reference when discussing a longitudinal direction or discussing lengths of the various structures within the rifled barrel 100. Specifically, length L′ denotes a length of the non-rifled portion 108, length L″ denotes a length of the rifled portion 106 with consistent or uniform land 110 heights, or diameter D″ between opposing lands 110, and length L″′ denotes a length of a transitional section 116 of the rifled portion 106 with sloping lands having changing land height and diameter D″. The specific values of lengths L′, L″, and L″′ may vary individually, and in relation to each other, as desired to achieve desired performance across varying parameters. An overall length of the cylindrical body 101 is a summation of lengths L′, L″, and L″′. A length of the rifled portion 106 is a summation of lengths L″ and L″′.
While methods of loading the projectile 120 into the rifled barrel 100 will vary between embodiments depending on the type of firearm the rifled barrel is a part of, certain structures and corresponding functions are common across all embodiments.
As shown in
The standard height is the height H of the lands 110 above the grooves 112 in the remaining, non-sloped length L″ of the rifled portion 106. The standard height is consistent within the same rifled barrel 100, but may vary between other rifled barrels. Further, the standard height of the grooves 110 is considered in an ideal barrel 100 that is does not include wear or fouling. In other words, along the transitional section 116, a diameter D″ between the lands 110 increases gradually moving along the transitional section 116 from the muzzle end 102 towards the breech end 104 until reaching the non-rifled portion 108, at which point the diameter D″ between the lands equals a diameter D′ between the grooves 112. Diameter D′ is the diameter between grooves zo 112. Diameters D″ and D′ between lands 110 and grooves 112 are measured between oppositely oriented sides of the cylindrical cavity, or at 180 degrees when viewed along a transverse cross-section. The slope of the transitional section 116, or rate of change between D″ and D′ along the transitional section, may be continuous or non-continuous. In other words, the slope of the transitional section 110 may be straight or curved. A diameter D of the non-rifled portion 108 is preferably equal to the diameter D′ between the grooves 112 of the rifled portion 106. This is important, along with the partial length L″′ of the rifled portion 106 with sloped lands 110 adjacent to the non-rifled portion 108, to the function of all embodiments of the rifled barrel 100. When propellant is ignited, or upon being loaded into the rifled barrel 100, forces act upon the bullet 124 to force it into the casing 122. Whether the bullet 124 is forced downward or backward into the casing 122, as with a bullet and sabot combination, or the casing is forced downward or backward over the bullet, as shown in
Such expansion of the projectile 120 to the full diameter of the non-rifled portion 108, as opposed to expansion around lands 110 in a fully rifled barrel, allows for a greater bite, or formation of the projectile around the lands, while the projectile travels through and out of the rifled barrel 100. This in turn promotes greater accuracy of the zo projectile 120 upon leaving the rifled barrel 100 and travelling towards its intended target.
While a particular projectile 120 is shown in the
Traditional breechloader rounds and bullets are also compatible with the rifled barrel embodiments described herein. In a breechloader firearm, the transitional section 116 does provide less wear on the rifled barrel 100 overall and provide increased performance to the bullet, as less force is wasted on the initial contact between the lands 110 and 116 and bullet and is instead transferred more efficiently into spinning the bullet along the lands 110 of the rifling.
Again, a cartridge or round typically compatible with a breechloader firearm may be interchangeable with the projectile 120 in the rifled barrel embodiment of
The rifled barrel 200 embodiment shown in
In this rifled barrel embodiment 200, the non-rifled portion is formed along an inner surface of a slidably insertable tube 250. The slidably insertable tube 250 is insertable through the breach end 204 of the rifled barrel 200. The insertable tube forming the non-rifled portion 208 may be preferable to avoid directly grinding or cutting down the lands 210 of a rifled barrel 200 to form a non-rifled portion.
This particular configuration is preferable in use with in-line muzzleloader firearms, wherein the rifled barrel 200 is removable from the in-line muzzleloader and the non-rifled portion 208 is accessible via the breech end 204 after removal of a breech plug 240 for cleaning.
The rifled barrel embodiments described herein may be used with either breechloader firearms (i.e. non-muzzleloader firearms) or muzzleloader firearms. Further, the firearms, either muzzleloaders or non-muzzleloaders, are not limited to rifles and handguns. The rifled barrel embodiments described herein may be used with any applicable firearm, including, but not limited to, handguns, long guns, rifles, zo shotguns, carbines, machine guns, submachine guns, automatic rifles, assault rifles, personal defense weapons, battle rifles, etc.
The rifled barrel embodiments described herein may be formed as a separable, discrete part of a firearm, or may be formed with one or more other constituent parts typically found in firearms. One skilled in the art would appreciate other parts of a firearm, either muzzleloader or breechloader, not shown and described can be combined with the rifled barrel embodiments shown and described to form a complete firearm. The invention provided herein relates particularly to the structure of the rifled barrel, and therefore other parts necessary to form a complete firearm are omitted for ease of reference.
| Number | Date | Country | |
|---|---|---|---|
| 62946049 | Dec 2019 | US | |
| 62961428 | Jan 2020 | US |
